Dynamic bandwidth switching for reducing power consumption in wireless communication devices

ABSTRACT

Systems, methods, apparatuses, and computer-program products for performing dynamic bandwidth switching between control signals and data signals of differing bandwidths are disclosed. A mobile device receives a control signal having a first bandwidth. The mobile device receives a data signal having a second bandwidth different from the first bandwidth. The control signal and the data signal are received over a single carrier frequency. The data signal is transmitted after the control signal such that the data signal and control signal are separated by a time interval. The time interval is based on a switching latency of the mobile device.

CROSS REFERENCE TO RELATED APPLICATIONS

The present application is a continuation application of U.S. patentapplication Ser. No. 16/186,297 filed Nov. 9, 2018, which is acontinuation application of U.S. patent application Ser. No. 15/617,960,filed Jun. 8, 2017, now U.S. Pat. No. 10,154,456, which is acontinuation application of U.S. patent application Ser. No. 15/393,736,filed Dec. 29, 2016, now U.S. Pat. No. 9,756,563, which is a divisionalapplication of U.S. patent application Ser. No. 14/846,051, filed Sep.4, 2015, now U.S. Pat. No. 9,572,106, which claims priority to and thebenefit of U.S. Provisional Patent Application No. 62/073,603, filedOct. 31, 2014, each of which is hereby incorporated by reference in itsentirety.

TECHNICAL FIELD

This application relates to wireless communication systems, and moreparticularly to signaling formats with varying signal bandwidth andassociated adaptation of transceivers to conserve power consumption inmobile devices and base stations.

BACKGROUND

The demand for wireless data services continues to increaseexponentially. As the demand for data grows, techniques capable ofdelivering higher data rates to mobile devices continue to be ofinterest. One way to deliver higher data rates is to increase thespectral bandwidth available to wireless communication systems.

Reflecting the trend to use increasing bandwidth, current versions of3rd Generation Partnership Project (3GPP) Long Term Evolution (LTE)networks have up to 100 megahertz (MHz) available for communication.Moreover, it is possible that future networks, such as fifth generation(or 5G) networks, may utilize several hundred MHz or more in an attemptmeet future demand for data services.

As system bandwidth increases, data transmission can increase roughlyproportionally without incurring a similar proportional increase incontrol overhead. Thus, in future time division multiplex (TDM) systemsthat multiplex control and data channels, there may be scenarios inwhich it would be inefficient for control channels to occupy as muchbandwidth as data channels. There are inefficiencies both becausespectral resources may be used unnecessarily that could be betterutilized for other purposes and because mobile devices would be tuned toa larger bandwidth than needed, thereby wasting energy resources. Thus,there is a need to more efficiently multiplex control and data channelsas available bandwidth increases in wireless communication systems.

SUMMARY

In one aspect of the disclosure, a method of wireless communicationincludes transmitting a control signal to a mobile device using a firstbandwidth, and transmitting a data signal to the mobile device using asecond bandwidth wider than the first bandwidth, wherein the controlsignal and the data signal are transmitted over a single carrierfrequency.

In an additional aspect of the disclosure, a method of wirelesscommunication in a mobile device includes receiving a control signalhaving a first bandwidth, and receiving a data signal having a secondbandwidth wider than the first bandwidth, wherein the control signal andthe data signal are received over a single carrier frequency.

In an additional aspect of the disclosure, a computer program productfor wireless communications includes a non-transitory computer-readablemedium having program code recorded thereon, the program code includingcode for causing a transmitter to transmit a control signal to a deviceusing a first bandwidth. The program code further includes code forcausing the transmitter to transmit a data signal to the device using asecond bandwidth wider than the first bandwidth, wherein the controlsignal and the data signal are transmitted over a single carrierfrequency.

In an additional aspect of the disclosure, a computer program productfor wireless communications includes a non-transitory computer-readablemedium having program code recorded thereon, the program code includingcode for causing a receiver to receive a control signal having a firstbandwidth. The program code further includes code for causing thereceiver to receive a data signal having a second bandwidth wider thanthe first bandwidth, wherein the control signal and the data signal arereceived over a single carrier frequency.

In an additional aspect of the disclosure, a mobile device includes anadjustable radio-frequency (RF) front end configured to receive acontrol signal having a first bandwidth, and receive a data signalhaving a second bandwidth wider than the first bandwidth, wherein thecontrol signal and the data signal are received over a single carrierfrequency.

In an additional aspect of the disclosure, a wireless communicationapparatus includes an amplifier, an analog-to-digital converter (ADC),an analog filter coupled between the amplifier and the ADC, and acontrol processor coupled to the amplifier, the ADC, and the analogfilter. The control processor is configured to, in response to receivingcontrol information from a control signal having a first bandwidth, setthe bandwidth of the amplifier and the ADC to a second bandwidth widerthan the first bandwidth, and set the sampling rate of the ADC accordingto the second bandwidth.

In an additional aspect of the disclosure, a wireless communicationapparatus includes a control processor configured to couple to an RFfront end, adjust the RF front end to receive a control signal having afirst bandwidth, and adjust the RF front end to receive a data signalhaving a second bandwidth wider than the first bandwidth, wherein thecontrol signal and the data signal are received over a single carrierfrequency.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates a wireless communication network, in accordance withvarious aspects of the present disclosure.

FIG. 2 is a high-level block diagram of an adjustable receiver inaccordance with various aspects of the present disclosure.

FIG. 3 illustrates a frame format and the corresponding powerconsumption of an RF front end during in accordance with various aspectsof the present disclosure.

FIG. 4 is a flowchart illustrating an exemplary method for receivingcontrol and data signals in accordance with various aspects of thepresent disclosure.

FIG. 5 illustrates another frame format and the corresponding powerconsumption of an RF front end during reception of the illustrated frameformat in accordance with various aspects of the present disclosure.

FIG. 6 is a flowchart illustrating another exemplary method forreceiving control and data signals in accordance with various aspects ofthe present disclosure.

FIG. 7 illustrates an example frame and signal structure for a frequencydivision multiplexing (FDM) system in accordance with various aspects ofthe present disclosure.

FIG. 8 is a protocol diagram illustrating transmissions between a basestation and a UE for an FDM system in accordance with various aspects ofthe present disclosure.

FIG. 9 is a protocol diagram illustrating signaling aspects between a UEand a base station to support dynamic bandwidth switching in accordancewith various aspects of the present disclosure.

FIG. 10 is a block diagram of a transceiver in accordance with variousaspects of the present disclosure.

FIGS. 11-16 illustrate additional embodiments of a frame format inaccordance with various aspects of the present disclosure.

DETAILED DESCRIPTION

The detailed description set forth below, in connection with theappended drawings, is intended as a description of variousconfigurations and is not intended to represent the only configurationsin which the concepts described herein may be practiced. The detaileddescription includes specific details for the purpose of providing athorough understanding of the various concepts. However, it will beapparent to those skilled in the art that these concepts may bepracticed without these specific details. In some instances, well-knownstructures and components are shown in block diagram form in order toavoid obscuring such concepts.

The techniques described herein may be used for various wirelesscommunication networks such as CDMA, TDMA, FDMA, OFDMA, SC-FDMA andother networks. The terms “network” and “system” are often usedinterchangeably. A CDMA network may implement a radio technology such asUniversal Terrestrial Radio Access (UTRA), cdma2000, etc. UTRA includesWideband CDMA (WCDMA) and other variants of CDMA. cdma2000 coversIS-2000, IS-95 and IS-856 standards. A TDMA network may implement aradio technology such as Global System for Mobile Communications (GSM).An OFDMA network may implement a radio technology such as Evolved UTRA(E-UTRA), Ultra Mobile Broadband (UMB), IEEE 802.11 (Wi-Fi), IEEE 802.16(WiMAX), IEEE 802.20, Flash-OFDMA, etc. UTRA and E-UTRA are part ofUniversal Mobile Telecommunication System (UMTS). 3GPP Long TermEvolution (LTE) and LTE-Advanced (LTE-A) are new releases of UMTS thatuse E-UTRA. UTRA, E-UTRA, UMTS, LTE, LTE-A and GSM are described indocuments from an organization named “3rd Generation PartnershipProject” (3GPP). CDMA2000 and UMB are described in documents from anorganization named “3rd Generation Partnership Project 2” (3GPP2). Thetechniques described herein may be used for the wireless networks andradio technologies mentioned above as well as other wireless networksand radio technologies, such as a next generation (e.g., 5^(th)Generation (5G)) network.

This disclosure recognizes that as available system bandwidth increases,the bandwidth utilized by data signals can be increased (and therebydata rate can be increased) without corresponding increases in controlchannel signaling. Frame formats are disclosed that utilize narrowbandcontrol signals and wideband data signals. The frame formats provide foradjustments to be made in mobile device receivers to receive controlsignals at one bandwidth and data signals at wider bandwidths. Areceiver can utilize a low-power mode to receive a control signal andthen increase bandwidth and power consumption to receive a data signal.A transition interval or period can be inserted between a control signaland a data signal to allow the receiver time to adjust to the varioussignal bandwidths.

Power consumption in a wireless communications receiver scales withreceived signal bandwidth. This disclosure relates generally to wirelesscommunication networks that employ control signals and data signals ofdifferent bandwidths. Receivers in such networks are provided to takeadvantage of and adjust to the different bandwidths to reduce powerconsumption. For example, power consumption in wireless devices can bereduced because control signals may occupy a smaller bandwidth than inconventional systems.

FIG. 1 illustrates a wireless communication network 100, in accordancewith various aspects of the disclosure. The wireless communicationnetwork 100 may be an LTE network or a next generation (e.g., 5G)network. The wireless network 100 may include a number of base stations110. A base station 110 may include an enhanced Node B in the LTEcontext. A base station may also be referred to as a base transceiverstation or an access point.

The base stations 110 communicate with user equipments (UEs) 120 asshown. A UE 120 may communicate with a base station 110 via an uplinkand a downlink. The downlink (or forward link) refers to thecommunication link from a base station 110 to a UE 120. The uplink (orreverse link) refers to the communication link from a UE 120 to a basestation 110.

The UEs 120 may be dispersed throughout the wireless network 100, andeach UE 120 may be stationary or mobile. A UE may also be referred to asa terminal, a mobile station, a subscriber unit, etc. A UE 120 may be acellular phone, a smartphone, a personal digital assistant, a wirelessmodem, a laptop computer, a tablet computer, etc. The wirelesscommunication network 100 is one example of a network to which variousaspects of the disclosure apply. Other examples are WLANs.

FIG. 2 is a high-level block diagram of an adjustable receiver 200. Theadjustable receiver 200 may be included in a UE 120. The adjustablereceiver 200 may include one or more antennas 210. If the adjustablereceiver 200 includes multiple antennas 210, any technique formultiple-input multiple-output communication (MIMO) may be employed. Forconvenience, the description will focus on one antenna 210 a and itsassociated components with the understanding that the descriptionapplies to each antenna and its associated components.

In this example, the adjustable receiver 200 includes an RF front end212 a. In this example, the RF front end 212 a includes an amplifier 215a, a mixer 220 a, an analog filter 225 a, and an analog-to-digitalconverter (ADC) 230 a in communication with the antenna 210 a as shown.The adjustable receiver 200 employs a zero intermediate frequency (IF)architecture in which a received signal at antenna 210 a is amplified byamplifier 215 a and then downconverted directly to baseband by mixer 220a in conjunction with local oscillator (LO) 240. A radio frequency (RF)amplifier, such as a low-noise amplifier (LNA), is an example of theamplifier 215 a.

The analog filter 225 a may be a low-pass filter with an adjustablebandwidth. The received signal is typically a sum of a desireddata-carrying signal, interference, and noise. In some scenarios, thebandwidth of the analog filter 225 a is set to prevent aliasing, permitthe desired signal to pass with relatively little distortion to ADC 230a, and attenuate out of band interference and noise.

The ADC 230 a receives an analog signal at its input and samples anddigitizes the analog signal to produce a digital output. The samplingrate of the ADC 230 a is sufficient to prevent or sufficiently limitaliasing of the signal and is generally at least twice the highestfrequency component of the input signal. The sampling rate of the ADC230 a may be adjustable to satisfy the desired sampling rate accordingto signals with different input bandwidths.

The adjustable receiver 250 further includes a baseband processor 245.The baseband processor 245 receives the signals from all receive chainsand performs demodulation and decoding (if needed) of the receivedsignals.

The adjustable receiver further includes a control processor 255. Thecontrol processor 255 may direct the operation of the adjustablereceiver 200. The control processor 255 generates one or more commandsignals (represented by dashed lines) intended for amplifiers 215,analog filters 225, ADCs 230, and/or the baseband processor 245. Thecommand signals may also be referred to herein as internal controlsignals to distinguish the nomenclature from the uplink and downlinkcontrol signals transmitted over wireless channels.

The adjustable receiver 200 further includes a memory 250. The memory250 may be any electronic component capable of storing informationand/or instructions. For example, the memory 250 may include randomaccess memory (RAM), read-only memory (ROM), flash memory devices inRAM, optical storage media, erasable programmable read-only memory(EPROM), registers, or combinations thereof. In an embodiment, thememory 250 includes a non-transitory computer-readable medium.

Instructions or code may be stored in the memory 250 that are executableby the baseband processor 245 and/or the control processor 255. Theterms “instructions” and “code” should be interpreted broadly to includeany type of computer-readable statement(s). For example, the terms“instructions” and “code” may refer to one or more programs, routines,sub-routines, functions, procedures, etc. “Instructions” and “code” mayinclude a single computer-readable statement or many computer-readablestatements.

The control processor 255 may be implemented using a general-purposeprocessor, a digital signal processor (DSP), an application specificintegrated circuit (ASIC), a field programmable gate array (FPGA) orother programmable logic device, discrete gate or transistor logic,discrete hardware components, or any combination thereof designed toperform the functions described herein. The control processor 255 mayalso be implemented as a combination of computing devices, e.g., acombination of a DSP and a microprocessor, a plurality ofmicroprocessors, one or more microprocessors in conjunction with a DSPcore, or any other such configuration.

The amplifiers 215, analog filters 225, and/or ADCs 230 may becomponents with adjustable parameters so that the adjustable receiver200 is able to adapt to receive signals of different bandwidths in sucha way that power consumption varies according to bandwidth. The powerconsumption generally decreases with decreasing bandwidth. For example,the amplifiers 215 and analog filters 225 may have bandwidths that areadjustable, with the bandwidths set according to the correspondingcommand signals. Furthermore, the ADCs 230 may have an adjustablesampling rate, with the sampling rates set according to thecorresponding command signal.

Consider an example scenario in which the adjustable receiver 200expects a relatively narrowband signal followed by a relatively widebandsignal. Prior to receiving the narrowband signal, the control processor255 can set the bandwidths of the amplifiers 215 and analog filters 225accordingly, and can set the sampling rate of the ADCs 230 accordingly.After receiving the narrowband signal but before receiving the widebandsignal, the control processor 255 can increase the bandwidths of theamplifiers 215 and analog filters 225 to accommodate the widerbandwidth, and can increase the sampling rate of the ADCs to alsoaccommodate the wider bandwidth. The greater the bandwidth of the signalto be received, the more power is needed to process the signal.

It is understood that the zero IF architecture of FIG. 2 is one of manyreceiver architectures that are capable of adjusting to receive signalsof various bandwidths. Many different receiver architectures inaccordance with the present disclosure may employ amplifiers, filters,and ADCs in various combinations whose parameters can be adjusted.

This disclosure is directed to any type of modulation scheme, butorthogonal frequency division multiplexing (OFDM) is used as arepresentative modulation. OFDM is a flexible modulation scheme thatprovides for adjusting the bandwidth of the transmitted signal in astraightforward manner.

OFDM modulation utilizes a number of subcarriers. The spacing betweensubcarriers may be fixed, and the total number of subcarriers utilizedmay be changed depending on the bandwidth of the signal. For example,the spacing between subcarriers may be 4 kHz and the number ofsubcarriers may be 100, in which case the signal bandwidth isapproximately 400 kHz (number of subcarriers times spacing betweensubcarriers), not counting any guard bands. Thus, one way to scalebandwidth using OFDM is to scale the number of subcarriers. There areother well-known ways to scale bandwidth of OFDM signals, such asscaling the frequency spacing between subcarriers. OFDM is demodulatedusing a fast Fourier transform (FFT), and the size of the FFT can bevaried according to the number of subcarriers. Thus, the basebandprocessor 245 may include at least one adjustable FFT per antenna toadapt the demodulation to different signal bandwidths. The controlprocessor 255 may control the baseband processor 245 to indicate FFTsize or other parameters to adapt the baseband processor 245 to OFDMsignals with parameters that vary according to bandwidth. After an OFDMsignal is formed, it can be transmitted using a separate singlehigh-frequency carrier, sometimes referred to as an RF carrier. Theavailable time-frequency resources may be partitioned into resourceblocks. Each resource block may cover N subcarriers (e.g., 12subcarriers) in one OFDM symbol duration.

Operation of the adjustable receiver 200 is described further withreference to FIG. 3. FIG. 3 illustrates a frame format 310 and thecorresponding power consumption 360 of an example RF front end, such asRF front end 212 a, during reception of the illustrated frame format.The frame format 310 is a TDM format in which time is divided intotransmission time intervals (TTIs). Control signals and data signals aretime division multiplexed within a TTI. FIG. 3 illustrates an examplesequence of transmitted signals within this frame format 310.

A TTI may refer to the duration of a transmission on the radio link. ATTI may be related to the size of the data blocks passed from the highernetwork layers to the radio link layer. In some embodiments, theduration of data symbols, such as OFDM symbols, is fixed, and there area predetermined number of data symbol periods during each TTI. Forexample, each TTI may be any number of symbol periods, such as 8, 10, or12 symbol periods, as examples.

In wireless communication systems, a downlink control signal may includeinformation for a UE related to establishing, maintaining, or ending adata session. For example, a downlink control signal in a TTI mayprovide information to a UE about whether a downlink data signal followsin the TTI, and, if so, the control signal may indicate a bandwidth ofthe data signal.

The frame format 310 is designed with a purpose of reducing powerconsumption in UE receivers. A control signal 315 is transmitted at thebeginning of each TTI. The control signal uses a relatively narrowbandwidth as compared to data signals. The bandwidth of control signalsis sufficient to convey control information to intended UE(s), and it isnot necessary to use the larger bandwidths used for data signals for therelatively small amount of control information. In a TTI, the controlsignal indicates whether there is a data signal following the controlsignal. In some embodiments, the bandwidth used for data signals isvariable, in which case the control signal also indicates the bandwidthused for the data signal that follows. Alternatively, in someembodiments, data signals always occupy a certain bandwidth (such as theentire bandwidth), in which case the bandwidth of the data signal isunderstood or implied and there is no need for the control signal toconvey bandwidth information.

Each of the transmitted signals is transmitted using a single carrierfrequency f_(c). Using a single carrier simplifies receivers as comparedto systems that use carrier aggregation. Carrier aggregation typicallyrequires the use of multiple LOs, whereas the signaling schemesdescribed herein can use only one LO. However, the approaches describedin the present disclosure can also be applied to multiple carrierfrequencies.

The frame formats disclosed herein, such as frame format 310, may applyregardless of the number of antennas employed in the transmitting entityor the receiving entity. For example, in a SISO system, the signal istransmitted from the transmitting antenna and received at the receiveantenna. As another example, in a MIMO system, the illustrated frameformats are transmitted from at least one antenna. Each antenna fromamong a plurality of antennas may transmit the same or a different pilotstructure. In one embodiment, the illustrated frame format 310 will bereceived by a receive antenna, and may be part of a composite signalthat is a sum of signals from a plurality of antennas.

In this example, in the n^(th) TTI (TTI_(n)), the control signal 315indicates to the designated UE that no data follows in the TTI.Adjustable receiver 200 can be used to receive the control signal 315.After the adjustable receiver 200 receives the control signal 315 inTTI_(n), RF front-end components 215, 225, and 230 can be temporarilyturned off or shut down by the control processor 255, placing theadjustable receiver 200 in a state of “microsleep.” For example, aswitch can be placed between a component, such as an amplifier 215, ananalog filter 225, and/or an ADC 230, and its power supply, with theswitch being opened for a period of time to shut down power to thecomponent. Another example of “microsleep” is placing a component in anidle state in which it receives a reduced amount of power to operate ina reduced capacity.

The RF power consumption 360 of an RF front end, such as the RF frontend 212 a in adjustable receiver 200, is illustrated in FIG. 3 duringreception of various signals. For example, during reception of controlsignal 315 in TTI_(n), the power consumption is represented by 365.After determining that there is no data, the adjustable receiver 200transitions to a state of microsleep, and the power consumption duringthat transition is represented by 370. The decrease in power consumptionis represented as a linear decrease over time, but the actual decreasein power consumption may be non-linear but decreasing over timenonetheless. During the interval in TTI_(n) after being placed inmicrosleep, the RF power consumption is much lower than when a signal isbeing received because amplifiers 215, analog filters 225, and ADCs 230have been shut down.

A short time before TTI_(n+1), the control processor 255 informs theamplifiers 215, analog filters 225, and ADCs 230 to power on prior toreceiving control signal 315 during TTI_(n+1). The power consumptionduring that transition is represented by 375, and the power consumptionduring reception of the control signal 315 in TTI_(n+1) is representedby 380. The components in receiver 200 that have been shut down need aperiod of time to power up sufficiently to receive a signal.

In this example, control signal 315 is followed by data signal 325 inTTI_(n+1). The baseband processor 245 demodulates the control signal 315and provides control signal information to the control processor 255.The information in the control signal 315 indicates to the controlprocessor 255 that a data signal will follow. In some scenarios, thedata signal 325 is a wider bandwidth than the control signal 315. Inresponse, control processor 255 informs amplifiers 215, analog filters225, and ADCs 230 to adjust appropriately for the wider bandwidth. Thatis, the bandwidths of the amplifiers 215 and analog filters 225 areincreased, and the sampling rate of the ADCs 230 is also increased. Insome embodiments, the control processor 255 also informs basebandprocessor 245 to adapt accordingly to the increased bandwidth. Forexample, for demodulation of OFDM signals, the control processor 255informs the baseband processor 245 to adjust FFT size or otherparameters appropriately in order to demodulate the incoming datasignal.

The frame format 310 may further provide for frequency divisionmultiplexing (FDM) among users. For example, the data signal 325 ofbandwidth B may be partitioned in the frequency domain with differentportions of the bandwidth B allocated to different users. The RF frontend 212 for a user may still be adjusted appropriately for the bandwidthB with extraction and demodulation of the desired portion beingperformed digitally in the frequency domain using OFDM techniques.

In one embodiment, the control signal 315 indicates not only that datawill follow but also indicates the bandwidth of the data signal 325. Inthis case the control processor 255 determines the bandwidth. In otherembodiments, the data signal 325 always occupies the same bandwidth,such as the entire available bandwidth, in which case the data signalbandwidth may be understood to be a certain value and there may be noneed to include an indication in the control signal. If the bandwidth ofthe data signals is allowed to vary, components of the adjustablereceiver 200 are adjusted from data signal to data signal to receiveusing just enough bandwidth sufficient to cover the bandwidth of thedata signal of interest, instead of always tuning to receive using theentire available system bandwidth.

There is a transition period 320 between the control channel 315 and thedata signal 325 to allow the adjustable receiver 200 to adjust to thedifferent bandwidth. The transition period 320 may be referred to as aswitching interval because the receiver 200 is switching from onebandwidth to another. The switching interval may be quantized to aninteger number of symbol periods, such as OFDM symbol periods. The powerconsumption during this transition period 320 is represented by 385, andthe power consumption during reception of the data signal 325 isrepresented by 390.

There is a transition period 330 between the data signal 325 and thenext control signal 315 in TTI_(n+2). The transition period 330 allowsthe adjustable receiver 200 time to transition to a smaller bandwidthfor control signal 315. The power consumed during the transition period330 is represented by 395.

Some conventional TDM systems typically do not include the transitionperiods 320 and 330 to allow a receiver to adjust. One reason is that insome conventional TDM systems the control signal is transmitted usingthe same bandwidth as the data signal so receivers do not need totransition between different bandwidths. Thus, the power consumed duringtransition periods 320 and 330 represent a power penalty for thesignaling scheme in FIG. 3 as compared to some conventional systems.However, there is a substantial power savings during reception of thecontrol signal 315 in the frame format illustrated in FIG. 3. The powersaving includes the difference in power between the RF power consumedduring reception of the data signal and the RF power consumed duringreception of the control signal. The corresponding energy savings iscomputed as an area under the power curves. Under some conditions, thetotal energy saving exceeds the energy penalty, in which case the frameformat and corresponding adjustable receiver 200 extends battery life ascompared to conventional TDM systems.

FIG. 4 is a flowchart illustrating an exemplary method 400 for receivingcontrol and data signals. The method 400 may be implemented in theadjustable receiver 200, and the method 400 is described with referenceto the adjustable receiver 200. The signals that are received in method400 are transmitted by a base station 110 or other type of access point.Instructions or code may be stored in the memory 250 that are executableby the control processor 255 in the adjustable receiver 200 of FIG. 2 toimplement the method 400.

The method 400 begins in block 410. In block 410 a narrowband controlsignal is received and processed by the adjustable receiver 200. Thecontrol signal is referred to as a narrowband control signal because itsbandwidth is typically lower than the data signals, as illustrated inthe signaling scheme in FIG. 3. In block 415, a decision is made whethera data signal follows the control signal in the current TTI. The controlsignal will contain this information, and the control signal isdemodulated to extract this information.

If it is determined that no data signal follows the control signal inthe current TTI, the method proceeds to block 440, in which the powerprovided to certain RF front-end components, such as amplifiers 215,analog filters 225, and/or ADCs 230, is reduced to place the componentsin a microsleep state. The control processor 255 may send signals to thecomponents in the receiver 200 to control their status as describedearlier. After a period of time, in block 445 the components aredirected to power up or “wake up” to prepare to receive another controlsignal in block 410. The receiver 200 may wait until just before thebeginning of the next TTI to request for the RF front-end components towake up.

If it is determined in block 415 that a data signal does follow thecontrol signal, the method proceeds to block 420. In block 420, an RFfront end 212 a of the receiver 200 is adjusted to receive the datasignal. As described earlier, the control signal may contain informationabout the expected bandwidth of the data signal. Alternatively, thebandwidth of the data signal may be understood to be a certain value. Ineither case, the RF front end is adjusted. The control processor 255controls the adjustment. The baseband processor 245 may also beadjusted.

Next in block 425 the data signal is received and processed. After thedata signal is received in block 425, the RF front end is adjusted toreceive a control signal in block 430 and the method returns to block410 to start again. The method 400 continues as long as desired for acommunication session. In some embodiments, a control signal istransmitted at the beginning of each TTI and no further control signalsare transmitted within each TTI. In other embodiments, at least oneadditional control signal is transmitted in each TTI. For example, theremay be a control signal at the beginning of a TTI and another controlsignal in the middle of the TTI.

FIG. 5 illustrates another frame format 510 and the power consumption ofan RF front end 560 during reception of the illustrated frame format.The frame format 510 is a TDM format in which time is divided intotransmission time intervals (TTIs) and control signals and data signalsare time division multiplexed. FIG. 5 illustrates a transmitted signalsequence within this frame format 510.

The transmitted signal sequence in the frame format 510 is differentthan the frame format 310 in that if a data signal is transmitted, thenext control signal is transmitted using the bandwidth as the datasignal so that there is no switching time or switching interval foradjusting an RF front end. Since there is no need to adjust the RF frontend, a data signal can be transmitted until the TTI boundary. Thesignaling format trades off the potential for energy savings with a morenarrowband control signal against the benefit of being able to eliminatedead time for signaling due to switching. Thus, the signaling schemeuses both narrowband and wideband control signals, depending on whetherthe control signal follows a data signal.

The similarities and differences between the signaling schemeillustrated in FIG. 5 and the signaling scheme in FIG. 3 can beunderstood with reference to FIG. 6. FIG. 6 is a flowchart illustratingan exemplary method 600 for receiving control and data signals. In FIG.6, blocks 410-425, 440, and 445 are the same as the corresponding blocksin FIG. 4.

After a data signal is received in block 425, the method 600 proceeds toblock 610 in which a wideband control signal is received. The controlsignal may be referred to as a wideband control signal because thebandwidth is the same as the previously received data signal, and datasignal bandwidth is typically larger than the narrowband control signalbandwidth. The control signal 515 in the frame format 510 in FIG. 5 isan example narrowband control signal, and the control signal 530 is anexample wideband control signal. The narrowband control signal 515 isfollowed by a transition period 520 to allow an RF front end to adjustto receive the data signal 525. There is no transition period neededbetween the data signal 525 and the control signal 530 because thebandwidths are the same.

As discussed previously with respect to FIG. 3, the frame format 510 mayfurther provide for FDM among users. For example, the data signal 525 ofbandwidth B may be partitioned in the frequency domain with differentportions of the bandwidth B allocated to different users. Likewise, thecontrol signal 530 may be partitioned similarly. The RF front end 212for a user may still be adjusted appropriately for the bandwidth B withextraction and demodulation of the desired portion being performeddigitally in the frequency domain using OFDM techniques.

Next in decision block 615, a determination is made whether a datasignal follows the wideband control signal in the TTI. If data followsthe wideband control signal, in one embodiment then the data istransmitted at the same bandwidth as the control signal, so there is noneed to adjust the RF front end, and the data signal is received inblock 620. In another embodiment, the data is transmitted generally at abandwidth B that may be larger or smaller than the control signalbandwidth, so there may be a transition period during which the RF frontend is adjusted to receive the data signal.

On the other hand, if there is no data signal following the widebandcontrol signal then the method 600 proceeds to block 440. In block 440,the power provided to certain RF front end components, such asamplifiers 215, analog filters 225, and/or ADCs 230, is reduced to placethe components in a microsleep state. After a period of time, in block445 the components are directed to power up or “wake up” to prepare toreceive another control signal in block 410. The receiver 200 may waituntil just before the beginning of the next TTI to request for the RFfront-end components to wake up. As part of the wake up process, thebandwidth and sampling rate(s) of the RF front end are set to receive anarrowband control signal. Instructions or code may be stored in thememory 250 of the adjustable receiver 200 that are executable by thecontrol processor 255 to implement the method 600.

FIG. 7 illustrates an example frame and signal structure for an FDMsystem. The carrier frequency for data designated for a given UE is notfixed and can vary. In the FDM scheme, the total system bandwidth can bedivided up into a plurality of frequency bands such that data signalsfor different UEs can be transmitted simultaneously in differentfrequency bands. For example the data signal for UE₁ 710 and the datasignal for UE₂ 720 overlap in time during TTI₁ but do not overlap infrequency. A carrier signal at the center frequency of each of the datasignals illustrated in FIG. 7 is used to transmit the various datasignals.

The bandwidth allocated for data signals for a given UE can vary overtime, as illustrated by comparing data signals 710 and 730 addressed toUE₁, for example. A base station may decide to vary the bandwidth for aparticular UE due to variations in amount of data available fortransmission versus time, for example.

Some conventional FDM schemes transmit OFDM signals using the fullavailable bandwidth for downlink transmissions, with different groups ofsubcarriers within the full signal allocated to different UEs. As aconsequence, each UE typically processes the entire bandwidth to extractthe group(s) of subcarriers allocated to the UE. In comparison, when theRF carrier frequency is allowed to vary from transmission totransmission, each UE is notified of what RF carrier is being used forits signals. However, the benefit of the approach with multiple RFcarriers is the bandwidth can be used more efficiently if data signalsare allowed to use different RF carriers so that each UE does not haveto process the entire bandwidth and can use the RF carrier devoted toit.

FIG. 8 is a protocol diagram illustrating the signaling aspects betweena UE 120 and a base station 110 to support FDM with variable bandwidths.In this example, control signals are transmitted via a different channelfrom data signals. The control channel may be in a different frequencyband or in a different time slot, as an example. A control signalindicates the center frequency (if center frequency is dynamic) and thebandwidth of an associated data signal. The data signal is then sentusing the designated bandwidth and center frequency. In a time intervalbetween the control signal and the data signal, the receiver of the UE120 is tuned to the data signal bandwidth. This process is repeated aslong as there is data to convey between base station 110 and UE 120.

The base station 110 may coordinate this process across different UEs120 to efficiently utilize the available spectral bandwidth. One exampleof this coordinated process was described with respect to FIG. 7.

FIG. 9 is a protocol diagram illustrating the signaling aspects betweena UE 120 and a base station 110 to support variable bandwidth signaling.First, the UE 120 transmits a capability message to the base station110. The capability message may provide one or more indicationscorresponding to a number of parameters and capabilities of the UE 110.The capability message may include an indication whether the UE 110 iscapable of dynamically switching between signals of various bandwidths.The capability message may further include an indication of switchinglatency for the UE 120, so that the base station 110 can respond byinserting or reserving a time interval between control and data signalsto allow the UE 120 to adjust its RF front end. The time intervalaccommodates the switching latency indicated by a UE.

Next the base station 110 transmits a response message in response tothe capability message. The response message may provide one or moreindications corresponding to a number of parameters and capabilities.For example, the response message may indicate that dynamic bandwidthswitching is activated. Dynamic bandwidth switching may be activated ordeactivated as frequently as desired during a connection. Thus, messagesindicating that dynamic bandwidth switching is activated or deactivatedmay be transmitted by the base station 110 as frequently as desired.

The response message may also indicate the time offset between a controlsignal and the corresponding data signal in a TTI. The time offset maybe based on the switching latency indicated in the capability message.The time offset would accommodate the latency needed to decode thecontrol signal and allow the RF front end to switch bandwidths. Theresponse message may also indicate whether the bandwidth is maintainedat a wide bandwidth of the data signal for the next control signal, asillustrated in FIG. 5, or returns to a narrow bandwidth, as illustratedin FIG. 3. Alternatively, a previous control signal may also indicatewhether the bandwidth is maintained at a wide bandwidth of the datasignal for a next control signal, as illustrated in FIG. 5, or returnsto a narrow bandwidth, as illustrated in FIG. 3.

Alternatively, the base station 110 may decide not to activate dynamicbandwidth switching. If dynamic bandwidth switching is not activated,the control signals occupy the same bandwidth as data signals and thereis no time offset between control signals and data signals.

After the capability message and the response message have beenexchanged, transmission of control and data information can proceed asneeded. In the example shown in FIG. 9, a control signal is transmittedby the base station 120 and received by the UE 110. Next, the UE 110adjusts its RF front end, and then a data signal is transmitted by thebase station 120 and received by the UE 110.

FIG. 10 is a block diagram of a transceiver 900 that implements aspectsof this disclosure. The transceiver 900 comprises antennas 210, basebandprocessor 245, memory 250, and controller/processor 255 as describedpreviously. The transceiver further includes RF receive (Rx) front ends910. Each RF Rx front end 910 may include an amplifier, an analogfilter, and an ADC as described with respect to FIG. 2. Other RF Rxfront end architectures are compatible with this disclosure. Forexample, some RF Rx front end architectures perform most processing inthe analog domain, and some RF Rx front end architectures perform mostprocessing in the digital domain. Furthermore, some RF Rx front endarchitectures perform most processing at an intermediate frequency (IF),rather than baseband. These RF Rx front ends can be made adjustable toaccommodate differences in control signal and data signal bandwidths.

The transceiver further includes RF transmit (Tx) front ends 920. EachRF Tx front end 920 accepts a stream of digital data symbols frombaseband processor and converts the digital data symbols to an analogsignal for transmission over the corresponding antenna 210.

The transceiver 900 is suitable for either a base station 110 or a UE120. When the transceiver 900 is in a transmit mode, the RF Tx frontends 920 are engaged, and the controller/processor 255 controls the RFTx front ends 920 as well as baseband processor 245 to generate signalsof various bandwidths. The combination of RF Tx front end 920 andbaseband processor 245 is an example of a transmitter. The combinationof RF Rx front end 910 and baseband processor 245 is an example of areceiver. An RF Rx front end 910 may comprise the RF front end 212described previously.

In addition to capabilities described earlier for demodulating OFDMsymbols, baseband process 245 may additionally be configured to modulateOFDM symbols. Modulation of OFDM symbols is well known in the art and insome embodiments an inverse FFT (IFFT) is performed to convert frequencydomain data to the time domain. As described earlier, there are varioustechniques for changing bandwidths of OFDM signals. One techniqueinvolves varying the number of subcarriers used for generating OFDMsignals.

Information and signals may be represented using any of a variety ofdifferent technologies and techniques. For example, data, instructions,commands, information, signals, bits, symbols, and chips that may bereferenced throughout the above description may be represented byvoltages, currents, electromagnetic waves, magnetic fields or particles,optical fields or particles, or any combination thereof.

FIG. 11 illustrates another frame format 1110. The frame format is a TDMformat in which time is divided into TTIs and control signals and datasignals are time multiplexed. FIG. 11 illustrates a transmitted signalsequence within this frame format 1110.

The control signals 1115 are narrowband control signals. In anembodiment, a base station allows one full TTI duration for bandwidthswitching delay of a receiver. There are at least two options forsignaling using control signals 1115. In a first option, the controlsignal 1115 in TTI_(n) has a bandwidth switch indicator to triggerwidening of RF front end bandwidth to receive wider bandwidth data inTTI_(n+1). In this option, the control signal 1115 in TTI_(n+1)indicates what frequency range is allocated for data in TTI_(n+1). In asecond option, data radio block allocation 1125 in TTI_(n+1) isallocated or prescheduled using control signal 1115 in TTI_(n). Once awide radio front end bandwidth is set up for TTI_(n+1), scheduling canreturn to normal (i.e., no prescheduling) for subsequent TTIs. Forexample, control signal 1115 in TTI_(n+2) indicates the use of dataresources 1135 and 1145 in TTI_(n+2).

An advantage of the first option is that the scheduler in a base stationonly needs to know that the UE will be scheduled in the next TTI to setthe indicator. The base station scheduler does not need to do theprescheduling and avoids a corresponding increase in complexity. Anadvantage of the second option is there is a saving of a control channelresource in that there is no bandwidth switch indicator.

The receiver bandwidth envelope is indicated in FIG. 11. The receiverbandwidth envelope represents the frequency range versus time utilizedby a receiver, such as adjustable receiver 200, in the frame format ofinterest. During transition period 1120 the receiver bandwidth maytransition from a relatively narrow bandwidth for reception of controlsignal 1115 to a relatively wide bandwidth (in this embodiment, the fullsystem bandwidth or full bandwidth available for data) for reception ofdata. Likewise, during transition period 1130 the receiver bandwidth maytransition from a relatively wide bandwidth to a relatively narrowbandwidth as shown.

FIG. 12 illustrates another frame format 1210. In this frame format adata signal may be allocated for only a latter fraction or portion of aTTI, such that there is enough time for the receiver bandwidth totransition from a narrow bandwidth to receive a control signal to awider bandwidth to receive a data signal. For example, in TTI_(n) thecontrol signal 1215 may indicate that there will be a data signal 1225later in the TTI. Thus, a smaller duration of a TTI than the example inFIG. 11 may be available for receiver bandwidth switching. During thetransition period 1220 the receiver bandwidth is increased. One suchexample increase of receiver is illustrated by the receiver bandwidthenvelope in FIG. 12.

Once the receiver is transitioned to a wider bandwidth in TTI_(n), dataallocation could span the entire TTI, including the option to multiplexwith the control channel in frequency. For example, control signal 1215in TTI_(n+1) may indicate the bandwidths of data signals 1235 and 1245.Control signals that are transmitted after the receiver has transmittedto a higher bandwidth may be referred to as wideband control signals,and in some embodiments a wideband control signal refers to a controlsignal and one or more data signals that are transmitted simultaneouslyin different frequency bands (i.e., frequency division multiplexed). Anexample of a wideband control signal is control signal 1215 in TTI_(n+1)in FIG. 12, and this control signal is frequency division multiplexedwith data signals 1235 and 1245. In some embodiments, during a timeinterval in which a wideband control signal is transmitted, thetransmitted signal includes a control signal portion and a data signalportion.

FIG. 12 also illustrates a countdown mechanism for returning a receiverto a narrow band for reception of control signals. In TTI_(n+2), controlsignal 1215 indicates there is no data within TTI_(n+2). Thus, TTI_(n+2)is a candidate for returning the receiver bandwidth to a narrowbandwidth using mechanisms described previously—for example with respectto FIG. 2. However, rather than having a receiver transition frequentlybetween bandwidths, a countdown mechanism is used. In the first TTI inwhich there is no data to transmit, a counter is set to a maximum value,such as four, three, two, one or any integer value. In the embodiment inFIG. 12, the maximum value is one. The counter is decremented eachsuccessive consecutive TTI that does not contain data. If a TTI doescontain data, the counter is reset to the maximum value. In the exampleof FIG. 12, in TTI_(n+3), if there is no data to transmit, the counteris decremented to zero. A counter value of zero indicates that thereceiver should thereafter reduce its bandwidth. For example, inTTI_(n+3), the receiver reduces its bandwidth as shown (the receiverenvelope transitions from a wide bandwidth to a narrow bandwidth duringtransition period 1230). An alternative to the countdown timer is thatthe receiver bandwidth is reduced to a narrow bandwidth in the first TTIthat does not contain data.

FIG. 13 illustrates another frame format 1310. Frame format 1310 issimilar to frame format 1110, except that for frame format 1310, anembodiment of a receiver is enhanced with bandwidth adaptation accordingto the data allocation. For example, in FIG. 11 during TTI_(n+1) thereceiver bandwidth is set to the system bandwidth or the maximumsupported data bandwidth, whereas in FIG. 13 the receiver bandwidthduring TTI_(n+1) is set just large enough to receive data signal 1325while remaining symmetric about center frequency f_(c).

Further, as in FIG. 11 there are at least two options for signalingusing control signals 1115. In a first option, the control signal 1115in TTI_(n) has a bandwidth switch indicator plus bandwidth informationto trigger widening of RF front end bandwidth to be just wide enough toreceive wider bandwidth data in TTI_(n+1). In a second option, dataradio block allocation 1125 in TTI_(n+1) is allocated or prescheduledusing control signal 1115 in TTI_(n). Once a wide radio front endbandwidth is set up for TTI_(n+1), scheduling can return to normal(i.e., no prescheduling) for subsequent TTIs. For example, controlsignal 1115 in TTI_(n+4) indicates the use of data resources 1335 inTTI_(n+4). As a further example, control signals 1115 in TTI_(n+2) andTTI_(n+3) indicate that there is no data in the respective TTIs, so thereceiver bandwidth remains narrow and the receiver can transition to astate of microsleep.

FIG. 14 illustrates another frame format 1410. When this frame format1410 is used the center frequency may not remain the same independent ofTTI. This frame format facilitates use of a receiver that can vary itscenter frequency and RF front end bandwidth. The receiver bandwidthenvelope is indicated.

The bandwidth of a receiver is centered on a frequency at the center ofcontrol signal 1415 in TTI_(n) and then the center is shifted duringtransition period 1420 to the frequency at the center of data signal1445.

This frame format 1410 combined with prescheduling of data signals 1445,1455, and 1465 using control signal 1415 implies that the controlsignals 1425 may be ignored by a receiver configured to receive datasignals 1445, 1455 and 1465. As illustrated in FIG. 14 preschedulingfractional TTIs for data signals may be performed. For example, datasignals 1445 and 1465 occupy a fraction of a TTI time interval, and theduration of the data signals may be indicated by control signal 1415.After data signal 1465, the RF front end may be re-tuned to a bandwidthfor control signal 1435 during transition period 1430.

FIG. 15 illustrates another frame format 1510. The frame format 1510 isan example TDM format in which control signals and data signals arereceived by a UE, and acknowledgement messages (ACKs) are transmitted bythe UE in response to reception of data signals. In an embodiment, anACK is used to indicate whether all or part of a preceding data signalwas received correctly. In this frame format 1510 the RF front endbandwidth of a receiver is maintained at the system bandwidth or maximumavailable data bandwidth until a TTI is received that does not have adata allocation. For example, in TTI_(n+2), control signal 1535indicates that there is no data in the TTI so a receiver can reduce itsbandwidth during transition period 1530 as shown. Guard periods may beinserted on either side of an ACK. For example, guard periods 1544 and1546 are inserted on either side of ACK 1445.

An example embodiment of scheduling data signals according to frameformat 1510 is as follows. Control signal 1515 in TTI_(n) may be used toschedule data signal 1565 for a fraction of the TTI. After receivingcontrol signal 1515 a receiver transitions its RF front end bandwidth toreceive data signal 1565 as shown. Alternatively (not illustrated),control signal 1515 in TTI_(n) could carry bandwidth switch indicator orprescheduling information, similar to the scheme described in FIG. 11,and data allocation is deferred until TTI_(n+1). This scheme avoidsallocation of data RBs for only a fraction of TTI (as in 1565), at theexpense of delayed start for the data transfer. Thereafter, the RF frondend bandwidth is maintained at a wide bandwidth until a control signalin a TTI indicates that there is no data in the TTI. Narrowband controlsignal 1525 indicates that data signal 1575 is present, so the receiveris configured to receive the data signal. The control signal 1525 mayuse a subset of the available subcarriers, and the portion of the datasignal 1575 that is simultaneous with the control signal 1525 may occupythe remaining available subcarriers. Control signal 1535 indicates thatthere is no data in TTI_(n+2), so the receiver reduces its RF front endbandwidth and may also transition to a microsleep state during thetransition period 1530.

Some advantages of the frame format 1510 include the following. First,for consecutive TTI data allocation, once the overhead is paid for RFbandwidth widening (causing delayed start of data radio blocks), in thesubsequent TTI there is no data radio block overhead. Second,enhancements for wideband-to-narrowband transitions, such as a countdowntimer or bandwidth switch indicator described with respect to FIG. 12,could also be applied.

FIG. 16 illustrates another frame format 1610. The frame format 1610 isan example TDM format in which control signals and data signals arereceived by a UE, and ACKs are transmitted by the UE in response toreception of data signals. An example embodiment of scheduling datasignals according to frame format 1610 is as follows. Control signal1615 in TTI_(n) may be used to schedule data signal 1620 for a fractionof the TTI. After receiving control signal 1615 a receiver transitionsits RF front end bandwidth to receive data signal 1620 as shown. Thereceiver switches back to a narrowband bandwidth for reception of eachcontrol signal as shown. For example, the receiver transitions to anarrow bandwidth during transition period 1640 and then receives controlsignal 1625 using a narrow bandwidth as shown. An advantage of the frameformat 1610 may include that bandwidth switching behavior is the sameacross TTIs.

Once it is appreciated how the frame formats in FIGS. 3 and 5 can beimplemented using the adjustable receiver 200 as described previously,it is readily understood that the frame formats in FIGS. 11-16 can beimplemented in a straightforward manner using the adjustable receiver200.

The various illustrative blocks and modules described in connection withthe disclosure herein may be implemented or performed with ageneral-purpose processor, a DSP, an ASIC, an FPGA or other programmablelogic device, discrete gate or transistor logic, discrete hardwarecomponents, or any combination thereof designed to perform the functionsdescribed herein. A general-purpose processor may be a microprocessor,but in the alternative, the processor may be any conventional processor,controller, microcontroller, or state machine. A processor may also beimplemented as a combination of computing devices (e.g., a combinationof a DSP and a microprocessor, multiple microprocessors, one or moremicroprocessors in conjunction with a DSP core, or any other suchconfiguration).

The functions described herein may be implemented in hardware, softwareexecuted by a processor, firmware, or any combination thereof. Ifimplemented in software executed by a processor, the functions may bestored on or transmitted over as one or more instructions or code on acomputer-readable medium. Other examples and implementations are withinthe scope of the disclosure and appended claims. For example, due to thenature of software, functions described above can be implemented usingsoftware executed by a processor, hardware, firmware, hardwiring, orcombinations of any of these. Features implementing functions may alsobe physically located at various positions, including being distributedsuch that portions of functions are implemented at different physicallocations. Also, as used herein, including in the claims, “or” as usedin a list of items (for example, a list of items prefaced by a phrasesuch as “at least one of” or “one or more of”) indicates an inclusivelist such that, for example, a list of [at least one of A, B, or C]means A or B or C or AB or AC or BC or ABC (i.e., A and B and C).

As those of some skill in this art will by now appreciate and dependingon the particular application at hand, many modifications, substitutionsand variations can be made in and to the materials, apparatus,configurations and methods of use of the devices of the presentdisclosure without departing from the spirit and scope thereof. In lightof this, the scope of the present disclosure should not be limited tothat of the particular embodiments illustrated and described herein, asthey are merely by way of some examples thereof, but rather, should befully commensurate with that of the claims appended hereafter and theirfunctional equivalents.

1. A method of wireless communication in a mobile device, comprising:transmitting a capability message indicating at least one capabilityassociated with the mobile device; receiving a response messageincluding a parameter based on the capability message; receiving acontrol signal, in accordance with the parameter, having a firstbandwidth, the control signal received over a single carrier frequency;and receiving a data signal having a second bandwidth different than thefirst bandwidth, the data signal received over the single carrierfrequency.
 2. The method of claim 1, wherein the capability messageindicates the mobile device is capable of dynamically switching betweensignals of different bandwidths.
 3. The method of claim 1, wherein thecapability message indicates a switching latency of the mobile devicefor switching between the first and second bandwidths of the singlecarrier frequency.
 4. The method of claim 1, wherein the parameterindicates that dynamic bandwidth switching is activated.
 5. The methodof claim 1, wherein the parameter indicates a time offset between thecontrol signal and the data signal.
 6. The method of claim 1, whereinthe parameter indicates that a subsequent control signal will bereceived at the first bandwidth.
 7. The method of claim 1, wherein theparameter indicates that a subsequent control signal will be received atthe second bandwidth.
 8. The method of claim 1, wherein the data signalis received after the control signal such that the data signal and thecontrol signal are separated by a time interval.
 9. The method of claim8, wherein the time interval is based on a switching latency of themobile device for switching between the first and second bandwidths ofthe single carrier frequency.
 10. The method of claim 1, wherein thefirst bandwidth is different from a system bandwidth of the singlecarrier frequency.
 11. A mobile device, comprising: an adjustableradio-frequency (RF) front end configured to: transmit a capabilitymessage indicating at least one capability associated with the mobiledevice; receive a response message including a parameter based on thecapability message; receive a control signal, in accordance with theparameter, having a first bandwidth, the control signal received over asingle carrier frequency; and receive a data signal having a secondbandwidth different than the first bandwidth, the data signal receivedover the single carrier frequency.
 12. The mobile device of claim 11,wherein the capability message indicates the mobile device is capable ofdynamically switching between signals of different bandwidths.
 13. Themobile device of claim 11, wherein the capability message indicates aswitching latency of the mobile device for switching between the firstand second bandwidths of the single carrier frequency.
 14. The mobiledevice of claim 11, wherein the parameter indicates that dynamicbandwidth switching is activated.
 15. The mobile device of claim 11,wherein the parameter indicates a time offset between the control signaland the data signal.
 16. The mobile device of claim 11, wherein theparameter indicates that a subsequent control signal will be received atthe first bandwidth.
 17. The mobile device of claim 11, wherein theparameter indicates that a subsequent control signal will be received atthe second bandwidth.
 18. The mobile device of claim 11, wherein thedata signal is received after the control signal such that the datasignal and the control signal are separated by a time interval.
 19. Themobile device of claim 18, wherein the time interval is based on aswitching latency of the mobile device for switching between the firstand second bandwidths of the single carrier frequency.
 20. The mobiledevice of claim 11, wherein the first bandwidth is different from asystem bandwidth of the single carrier frequency.